Immersion freezing of cell monolayers for cryo-electron tomography

Scanning x-ray nanodiffraction on Dictyostelium discoideum

We have performed scanning x-ray nanobeam diffraction experiments on single cells of the amoeba Dictyostelium discoideum. Cells have been investigated in 1), freeze-dried, 2), frozen-hydrated (vitrified), and 3), initially alive states. The spatially resolved small-angle x-ray scattering signal shows characteristic streaklike patterns in reciprocal space, which we attribute to fiber bundles of the actomyosin network. From the intensity distributions, an anisotropy parameter can be derived that indicates pronounced local variations within the cell. In addition to nanobeam small-angle x-ray scattering, we have evaluated the x-ray differential phase contrast in view of the projected electron density. Different experimental aspects of the x-ray experiment, sample preparation, and data analysis are discussed. Finally, the x-ray results are correlated with optical microscopy (differential phase contrast and confocal microscopy of mutant strains with fluorescently labeled actin and myosin II), which have been carried out in live and fixed states, including optical microscopy under cryogenic conditions.

Immersion freezing of biological specimens: rationale, principles, and instrumentation

Cryo-transmission electron microscopy (cryo-TEM) allows the visualization of biological specimens within their native, hydrated environment at nanometer resolution. To prevent the formation of destructive ice crystals, an extremely high cooling rate has to be achieved in the freezing process. For samples that are inherently thin enough, ranging from macromolecules to peripheral parts of spread cells, this can be accomplished by plunging the sample into a cryogen. This approach, known as “immersion freezing,” is an essential preparation technique in structural, molecular, and cell biology. In this article, we discuss the advantages of cryo-EM, the scope of specimens that can be visualized using this technique, the method of immersion freezing, and the instrumentation available. In particular, we focus on the new semiautomatic immersion freezer by Leica Microsystems (“EM GP”).